A large vessel having a very small circular hole of diameter 1 mm at the bottom is filled with water. Up to what maximum height (in cm) water can be filled in the vessel so that there is no leakage? `["surface tension of water "=7.5xx10^(-2)Nm^(-1) and g=10ms^(-2)]`

A vessel whose , bottom has round holes with diameter 0.1 mm , is filled with water. The maximum height up to which water can be filled without leakage is

A vessel whose bottom has round holes with diameter of 1 mm is filled with water Assuming that surface tension acts only at holes, then the maximum height to which the water can be filled in vessel without leakage is (given surface tension of water is 75xx10^(-3)N//m) and g=10m//s^(2)

A vessel, whose bottom has round holes with diameter of 0.1 mm , is filled with water. The maximum height to which the water can be filled without leakage is (S.T. of water =75 dyne/cm , g=1000 cm/s)

There is a circular hole of diameter d =140 mu m at the bottom of a vessel containing mercury . The minimum height of mercury layer so that the mercury will not flow out of this hole is ( Surface tension, sigma =490 xx 10^(-3) Nm^(-1))

A small hollow sphere having a small hole in it is immersed in water to a depth of 50cm, before any water penetrates into it. Calculate the radius of the hole, if the surface tension of water is 7.2 xx 10^(-2) Nm^(-1) .

A vessel containing mercury has a hole at its bottom. The diameter of the hole is 60 xx 10^(-6) m . Find the maximum height of mercury in the vessel so that it does not flow out through the hole. Surface tension of mercury is 54 xx 10^(-2) N//m .

Two long capillary tubes of diameter 5.0 mm and 4.0 mm are held vertically inside water one by one . How much high the water will rise in each tube ? ( g = 10 m//s^(2) , surface tension of water = 7.0 xx 10^(-2) N/m)

A long capillary tube of radius r = 1 mm open at both ends is filled with water and placed vertically. What will be the height (in cm ) of the column of water left in the capillary walls is negligible. (surface tension of water is 72 "dyne"//"cm" and g = 1000 "cm"//"sec"^(2) )

What is the difference of pressure between the inside and outside of a spherical drop of water of radius 1mm? Surface tension of water = 7.2 xx 10^(-2)Nm^(-1)

Calculate the pressue inside air bubble of diameter 0.2 mm situated just below the surface of water. Surface tension of water is 72 xx 10^(-3) Nm^(-1) .